ASTM E2088-06(2021)

This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the
Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.
Designation: E2088 − 06 (Reapproved 2021)
Standard Practice for
Selecting, Preparing, Exposing, and Analyzing Witness
Surfaces for Measuring Particle Deposition in Cleanrooms
and Associated Controlled Environments
This standard is issued under the fixed designation E2088; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope Contamination on Surfaces
F312 Test Methods for Microscopical Sizing and Counting
1.1 This practice is intended to assist in the selection,
Particles from Aerospace Fluids on Membrane Filters
preparation, exposure, and analysis of witness surfaces for the
purpose of characterizing particle deposition rates in clean- 2.2 ISO Standard:
ISO 14644-1 Cleanrooms and Associated Controlled
rooms and associated controlled environments, particularly for
aerospace applications. Environments—Part 1: Classification of Air Cleanliness
2.3 Government Standards:
1.2 Requirements may be defined in terms of particle size
Fed-Std-209 Airborne Particulate Cleanliness Classes in
distribution and count, percent area coverage, or product
Cleanrooms and Clean Zones
performance criteria such as optical transmission or scatter.
IEST-STD-CC1246 Product Cleanliness Levels and Con-
Several choices for witness surfaces are provided.
tamination Control Program
1.3 The values stated in SI units are to be regarded as
standard. No other units of measurement are included in this NOTE 1—The Institute of Environmental Sciences and Technology has
several Recommended Practices which may also be useful.
standard.
1.4 This standard does not purport to address all of the
3. Terminology
safety concerns, if any, associated with its use. It is the
3.1 Definitions:
responsibility of the user of this standard to establish appro-
3.1.1 bidirectional reflectance distribution function
priate safety, health, and environmental practices and deter-
(BRDF)—the scattering properties of light reflected off
mine the applicability of regulatory limitations prior to use.
surfaces, expressed as the ratio of differential outputs of
1.5 This international standard was developed in accor-
radiance divided by differential inputs of radiance. Surface
dance with internationally recognized principles on standard-
contaminants scatter the incident radiation in all directions and
ization established in the Decision on Principles for the
withvariableintensities.TheBRDFisamethodtoquantifythe
Development of International Standards, Guides and Recom-
spatial distribution of the scattered energy.
mendations issued by the World Trade Organization Technical
Barriers to Trade (TBT) Committee. 3.1.2 cleanliness level—an established maximum allowable
amount of contamination in a given area or volume, or on a
2. Referenced Documents (Note 1)
component.
2.1 ASTM Standards:
3.1.3 cleanroom—an environmentally conditioned area in
E1216 Practice for Sampling for Particulate Contamination
which temperature, humidity, and airborne contaminants are
by Tape Lift
controlled by design and operation. High-efficiency particulate
F24 Test Method for Measuring and Counting Particulate
air (HEPA) filters or better are usually required to achieve the
air cleanliness level. Air particulate cleanliness is classified in
accordance with Fed-Std-209 or ISO 14644-1.
This practice is under the jurisdiction of ASTM Committee E21 on Space
Simulation andApplications of Space Technology and is the direct responsibility of
Subcommittee E21.05 on Contamination.
Current edition approved Sept. 1, 2021. Published October 2021. Originally Available fromAmerican National Standards Institute (ANSI), 25 W. 43rd St.,
approved in 2000. Last previous edition approved in 2015 as E2088 – 06(2015). 4th Floor, New York, NY 10036, http://www.ansi.org.
DOI: 10.1520/E2088-06R21. Although Fed-Std-209 has been cancelled, it still may be used and designations
For referenced ASTM standards, visit the ASTM website, www.astm.org, or in Fed-Std-209 may be used in addition to the ISO designations.
contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM Available from Institute of Environmental Sciences and Technology (IEST),
Standards volume information, refer to the standard’s Document Summary page on Arlington Place One, 2340 South Arlington Heights Road, Suite 100, Arlington
the ASTM website. Heights, IL 60005-4516, http://www.iest.org.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
E2088 − 06 (2021)
3.1.4 contaminant—unwanted molecular and particulate particle detected by automatic instrumentation. The equivalent
matter that could affect or degrade the performance of the diameter is the diameter of a reference sphere having known
components upon which they reside. properties and producing the same response in the sensing
instrument as the particle being measured; (3) the diameter of
3.1.5 contamination—a process of contaminating.
a circle having the same area as the projected area of a particle,
3.1.6 contamination control—organized action to control
intheplaneofobservation,observedbyimageanalysis;(4)the
the level of contamination.
size defined by the measurement technique and calibration
3.1.7 controlled area—an environmentally controlled area,
procedure.
operated as a cleanroom, but without the final stage of HEPA
3.1.18 particulate contamination—discrete mass of solid
(or better) filters used in cleanrooms.
matter, size often measured in micrometres (µm), which
3.1.8 critical surface—any surface of an item or product
adversely affects critical surfaces of component and hence
which is required to meet established cleanliness level require-
system performance.
ments.
3.1.19 percent area coverage(PAC)—fractionofthesurface
3.1.9 demonstrated equivalence—the condition in which a
that is covered by particles, reported in percent as total particle
method of measurement has passed a series of tests to show
projected area divided by total area of the surface.
that it gives equivalent results to those of a standard measure-
3.1.20 precision cleaning—cleaning of hardware surfaces
ment.
approved by established facility methods or methods specified
3.1.10 environmentally controlled area—cleanrooms, con-
or provided by the customer with verification to a specified
trolled areas, good housekeeping areas, and other enclosures
cleanliness level.
that are designed to protect hardware from contamination.
3.1.21 visibly clean—absence of particulate or molecular
Cleanliness is achieved by controlling air purity, temperature,
contaminants when viewed from a specified distance with
humidity, materials, garments, and personnel activities.
normal (or corrected to normal) vision with a specified
3.1.11 fiber—a particle >100 µm in length with a length to
illumination level.
diameter ratio of ten or more.
3.1.22 witness surface (WS)—a contamination-sensitive
3.1.12 image analysis—the measurement of size, shape,
material used instead of direct evaluation of a specific surface
number, position, orientation, brightness, and other parameters
when that surface is either inaccessible or is too sensitive to be
of small objects using the combination of a microscope, an
handled.
imaging sensor, and a dedicated computer system. Image
3.1.22.1 optical witness surface (OWS)—witness surface
analysis can be used to perform particle counts or measure
fromwhichcontaminantsmaybeanalyzedbyopticalmethods.
particle dimensions automatically, with far greater accuracy
3.1.22.2 particle witness surface (PWS)—witness surface
than manual techniques.
from which particulate contaminants may be analyzed by
3.1.13 micrometre (µm)—a unit of measurement equal to
standard optical or electron microscopic methods.
one millionth of a metre, or approximately 39 millionths of an
inch, for example, 25 µm is approximately 0.001 in. The term
4. Summary of Practice
“micron” has been used but is not a recommended SI unit.
4.1 Particle deposition in controlled environments is deter-
3.1.14 nonvolatile residue(NVR)—solublematerialremain-
mined by collecting particles on a clean witness surface for a
ing after evaporation of a filtered volatile fluid or precipitate
specified period of time or operational activity, then retrieving
from a gas phase, usually reported in milligrams per unit area
the witness surface and quantifying the particle population
(or volume).
collected.
3.1.15 particle deposition—the settling of airborne particles
4.2 Witness surfaces (WS) are typically surfaces that lend
onto surfaces resulting from electrostatic or dynamic
themselves to traditional microscopic or image analysis tech-
conditions, or both, in cleanrooms or other controlled environ-
niquesforsizingandcountingparticlesonthesurface,butmay
ments.
be an optical surface that is evaluated on the basis of the
3.1.16 particle fallout(PFO)—astandardparticledeposition
changeinitsopticalpropertiesormaybeawitnesssurfacethat
method used by the European aerospace community that uses
best represents the surface material of interest which is
black glass witness surfaces and measures particle scatter in
subsequentlyevaluatedbyextractingasamplefromthesurface
parts per million.
and sizing and counting particles removed from the witness
surface.
3.1.17 particle size—(1) the apparent maximum linear di-
mension of a particle in the plane of observation, as observed
4.3 This practice does not address real time particle depo-
with an optical microscope; (2 ) the equivalent diameter of a
sition measurements involving particle counters on site with
continuous recording over a specified period of time.
The Euramark Model 255 PFO photometer has been found to be satisfactory.
5. Significance and Use
The sole source of supply of the apparatus known to the committee at this time is
Euramark, 834 East Rand Rd., Unit 6, Box 823, Mt. Prospect, IL 60056. If you are
5.1 Thispracticeprovidesastandardapproachtomeasuring
aware of alternative suppliers, please provide this information to ASTM Interna-
particle deposition, or fallout, in cleanrooms and other con-
tional Headquarters.Your comments will receive careful consideration at a meeting
of the responsible technical committee, which you may attend. trolledenvironments.Itisbasedontheuseofawitnesssurface
E2088 − 06 (2021)
to collect particles that deposit from the surrounding environ- 6.3.1 The PFO instrument uses a smooth black glass plate
ment and subsequently sizing and counting the particles by 40 by 45 mm protected from unintentional sedimentation by a
conventional methods. Several options are introduced, with plate holder. The effective sampling surface is circular with a
diameter of 25 mm.
limitations and guidelines for selecting the best choice for the
intended application.
6.3.2 Silicon wafers or disks shall be selected for image
analysis or other surface scanning methods.
5.2 This practice is applicable across numerous industries
including aerospace, microelectronics, and pharmaceuticals.
6.4 Optical Witness Surfaces, (that is, mirrors or lenses)
shall be selected to best represent the critical surface of interest
6. Selecting Witness Surfaces in the environment being evaluated. Reflectance or transmis-
sion measurements shall be made in the wavelengths of
6.1 ConsiderationsforselectingWSincludeavailablemeth-
interest, and the OWS must be the correct size and shape for
ods of analysis, precision and accuracy required, size of
the instrumentation planned for use.
particles of concern, actual material of critical surfaces of
concern, and cost. Preferably, the WS should be a surface 6.5 Gravimetric Methods—A gravimetric method can also
be used, whereby a large witness surface is rinsed with solvent
material which best represents the actual critical surface and
should be analyzed using the method which best represents the to extract the particles, filtered onto a dry, preweighed mem-
brane filter, and then dried and reweighed on a laboratory
actual performance characteristics of interest. Additionally,
balance with a resolution of 0.01 mg. The difference in weight
certain surfaces may become charged, especially in dry
can be a relative quantitative analysis of deposition based on
environments, and this charging can effect the particle deposi-
weight. Note, the efficiency of the extraction method must be
tion. IfWS are to monitor a vacuum environment they must be
known or estimated.Apreweighed membrane filter could also
made of low-outgassing, vacuum-compatible materials and
be used as the witness surface thus eliminating the extraction
held securely in vacuum-compatible, low-particle shedding
step.Additionally, a quartz crystal microbalance with adhesive
holders.
surfaces can measure accumulated mass in situ.
6.2 Microscopic Evaluation—When microscopic sizing and
counting of particles is the planned method of analysis, select
7. Preparation of Witness Surfaces
one of the following PWS, each of which is easily evaluated
7.1 Witness Surface Holders—Holders should be designed
directly after exposure. Microscopic sizing and counting shall
to retain the witness surface securely and maximize the surface
be performed in accordance with Method F24 or Test Methods
exposure. They should be made from smooth, cleanable
F312.
materialssuchasplastic,anodizedaluminum,orstainlesssteel.
6.2.1 Membrane Filters, should be gridded for ease in
A noncontact, easily removable, protective cover is required
microscopic particle counting and precleaned before exposure.
which prevents the collection of particulate contamination
Amembranefiltercanbepreparedaseitheratackyortack-free
during transport of the surfaces between the test laboratory and
surface. The membrane filter is cleaned and then either (1)
the controlled environment being evaluated. Holders should
immediately placed in a cleaned petri dish, (2) dipped into
have captive fasteners and tethers to prevent the holder or
trichloroethylene or methyl chloroform first so it will fuse to
associated hardware from impacting critical surfaces if
the plastic petri dish, or (3) dipped into a prefiltered tacky
dropped. Holders should also be designed to be secured in the
adhesiveanddriedinacleanedpetridish.Thepetridishisthen
facility being evaluated in either a vertical or horizontal
covered and transported to the area being tested.
orientation.
6.2.2 Gridded Counting Slides, such as those used
...